KR20160049807A - Apparatus and method controlling electronic parking brake of vehicle - Google Patents

Abstract

The present invention relates to an apparatus for controlling an electronic parking brake (EPB) of a vehicle. According to an embodiment of the present invention, the apparatus for controlling an EPD of a vehicle comprises: an EPB driving unit driving an EPB; a main MCU unit controlling the EPB driving unit; and a sub-MCU unit monitoring the state of the main MCU unit, determining whether or not the main MCU unit malfunctions as a result of monitoring, controlling the EPB driving unit acting as the main MCU unit when hardware of the main MCU unit malfunctions, and branching the main MCU unit to an emergency interrupt to enable the main MCU unit to control the EPB driving unit when software of the main MCU unit malfunctions. The present invention releases the EPB using the sub-MCU in order to improve driver convenience.

Description

Field of the Invention [0001] The present invention relates to a vehicle EPB control apparatus and method,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a device and a method for controlling a vehicle EPB (Electronic Parking Brake), and more particularly, to a technique for preventing a secondary accident or the like caused by stopping a vehicle by driving an EPB by a sub MCU when a main MCU fails.

Today, the automotive industry is pursuing a variety of technologies, such as technologies that improve the performance of the vehicle itself, vehicle design techniques, and techniques for devices inside the vehicle. In addition, the vehicle has a risk inherent in its inherent nature, and research and development of technology for safe driving is actively pursued in accordance with changes in society's overall awareness of safe driving.

In this paradigm, many technologies for improving the performance of EPB (Electronic Parking Brake) of a vehicle have been proposed. Of these technologies, research and development of technology for controlling EPB is also active.

The EPB system electronically controls the driving of the parking brake, which means that even if the driver does not operate the parking brake manually, it will automatically operate if the vehicle is stopped or there is a risk of the vehicle rolling back from the hill Keep the car parked or stopped.

The EPB system includes an EPB actuator and an EPB ECU (Electronic Control Unit) to generate parking braking force on the rear wheels of the vehicle. The EPB actuator is a mechanical device that generates a parking braking force on the rear wheel in accordance with a control signal of the EPB ECU. The EPB actuator includes a motor rotating forward and backward, and the parking brake force is generated on the rear wheel of the vehicle by forward rotation or reverse rotation of the motor. And causes the generated parking braking force to be released.

The EPB ECU includes a main microcontroller unit (main microcontroller unit) for controlling the sensor / data input / output and the external switch input / output, control logic for driving the actuator directly related to the vehicle braking, And a dual MCU unit of a sub microcontroller unit (sub MCU unit) that only performs a redundancy check on unrelated sensors or switches.

However, since the main MCU unit controls the control logic for driving the actuator directly related to the vehicle braking, and the sub MCU unit performs only the surplus check for the sensors and switches not directly related to the vehicle braking, There is a problem that the vehicle must remain standing on the road when the main MCU fails, and further, a secondary accident such as a collision with the rear vehicle may be caused.

The embodiment of the present invention is intended to solve the inconvenience caused when a problem occurs in the main MCU in the state that the EPB is operated. In this case, by releasing the EPB from being locked by using the sub MCU, The purpose of this is to prevent secondary accidents on the road.

Further, the embodiment of the present invention aims to improve the convenience of the vehicle driver by allowing the driver of the vehicle to go directly to the garage without pulling the vehicle by releasing the EPB from being locked by using the sub-MCU.

In addition, the embodiment of the present invention divides the failure of the main MCU into a hardware malfunction and a software malfunction, and by releasing the EPB in a locked state in other cases in each case, It is aimed at solving it.

According to an embodiment of the present invention, the EPB controller includes an EPB driver for driving an EPB (Electronic Parking Brake), a main MCU for controlling the EPB driver, a main MCU for monitoring the state of the main MCU, The main MCU unit is controlled by the main MCU unit and the main MCU unit is branched to an emergency interruption if the main MCU unit is in a software failure state, And a sub MCU unit for controlling the EPB driver.

The sub MCU unit determines whether the EPB driving unit is in operation when the main MCU unit is in failure, and when the main MCU unit is in hardware failure, the sub MCU unit can control the EPB driving unit have.

The sub MCU unit may cause the main MCU unit to branch the main MCU unit to the emergency interruption so that the main MCU unit controls the EPB driving unit when the EPB driving unit is in operation and the main MCU unit has a software failure.

The main MCU unit may operate the EPB driver by applying a high signal to the EPB driver, and may control the EPB driver by applying a pulse width modulation (PWM) signal to the EPB driver.

When the main MCU unit has a hardware failure, the sub MCU unit applies a high signal to the EPB driving unit to block the main MCU from applying the PWM signal to the EPB driving unit, applies the PWM signal to the EPB driving unit, The EPB driving unit can be controlled.

And a warning unit for informing the vehicle driver of the failure of the main MCU unit when the main MCU unit fails as a result of the determination in the sub MCU unit.

According to an embodiment of the present invention, the EPB control method includes a monitoring step of monitoring a state of a main MCU unit, a failure determination step of determining whether the main MCU unit has a failure through the monitoring result, The main MCU unit branches the main MCU unit to an emergency interruption when the main MCU unit is in a software failure state and the main MCU unit controls the EPB driving unit And a second control step for controlling the second control step.

Further comprising an operation determining step of determining whether the EPB driving unit is in operation when the main MCU unit is in failure, wherein the first control step is performed when the EPB driving unit is in operation and the main MCU unit is in hardware failure, The MCU unit can control the EPB driving unit.

In the second control step, when the EPB driving unit is in operation and the main MCU unit has a software failure, the sub MCU unit branches the main MCU unit to an emergency interrupt so that the main MCU unit controls the EPB driving unit.

In the first control step, the sub MCU unit applies a high signal to the EPB driving unit to block the main MCU from applying the PWM signal to the EPB driving unit, and then the sub MCU unit supplies the PWM signal So as to control the EPB driving unit.

And a warning step of informing a vehicle driver of the failure of the main MCU unit when the main MCU unit fails as a result of the determination in the sub MCU unit.

The embodiment of the present invention is intended to solve the inconvenience caused when a problem occurs in the main MCU in the state that the EPB is operated. In this case, by releasing the EPB from being locked by using the sub MCU, It is effective to prevent a secondary accident on the road caused by the accident.

In addition, the embodiment of the present disclosure has an effect of improving the convenience of the driver of the vehicle because the EPB can be released from the locked state by using the sub-MCU so that the vehicle driver can go directly to the repair shop without towing the vehicle.

In addition, the embodiment of the present invention divides the failure of the main MCU into a hardware malfunction and a software malfunction, and by releasing the EPB in a locked state in other cases in each case, There is an effect to solve.

1 is a block diagram of an EPB control apparatus according to an embodiment of the present invention.
2 is a flowchart sequentially illustrating a process of controlling an EPB of an EPB control apparatus according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

In describing the embodiments, descriptions of techniques which are well known in the technical field to which this specification belongs and which are not directly related to this specification are not described. This is for the sake of clarity without omitting the unnecessary explanation and without giving the gist of the present invention.

For the same reason, some of the components in the drawings are exaggerated, omitted, or schematically illustrated. Also, the size of each component does not entirely reflect the actual size. In the drawings, the same or corresponding components are denoted by the same reference numerals.

Hereinafter, an EPB control apparatus according to an embodiment of the present invention will be described with reference to FIG.

1 is a block diagram of an EPB control apparatus according to an embodiment of the present invention.

Referring to FIG. 1, a vehicle EPB control apparatus 100 according to an embodiment of the present invention includes an EPB driving unit 10, a main MCU unit 20, and a sub MCU unit 30.

The EPB driving unit 10 is an apparatus that drives an EPB (Electronic Parking Brake), and may be composed of an EPB motor 13, a motor driver 11, and a transistor 15. The EBP driver 10 also includes a main EPB activation line EN_MAIN line, a sub EPB activation line EN_SUB line, a main PWM signal input line PWM_MAIN line, a sub PWM signal input line PWM_SUB line, Fail / Safe_MAIN), and a sub fail safe line (Fail / Safe_SUB).

The main MCU unit 20 is an apparatus for controlling the EPB driving unit 10. [ The main MCU unit 20 controls the EPB driving unit 10 when the main MCU unit 20 is normal and a high signal is applied to the main EPB activation line (EN_MAIN line) of the EPB driving unit 10 shown in FIG. And operates the EPB driving unit 10. Thereafter, a PWM (Pulse Width Modulation) signal is applied to the main PWM signal input line (PWM_MAIN line) of the EPB driving unit 10 to control the EPB driving unit 10. In this case, a Low signal is applied to the sub EPB activation line (EN_SUB line), a High signal is applied to the main fail safe line (Fail / Safe_MAIN), and a Low signal is inputted to the sub fail safe line (Fail / Safe_SUB). At this time, the EPB driving unit 10 is controlled by the main MCU unit 20.

The sub MCU unit 30 monitors the state of the main MCU unit 20. [ Through the monitoring result, the sub MCU unit 30 determines whether the main MCU unit 20 is faulty. The sub MCU unit 30 controls the EPB driving unit 10 to act on the main MCU unit 20 when the main MCU unit 20 has a hardware failure. The sub MCU unit 30 branches the main MCU unit 20 to the emergency interruption when the main MCU unit 20 has a software failure and controls the main MCU unit 20 to control the EPB driving unit 10 do.

The sub-MCU unit 30 monitors the state of the main MCU unit 20 basically by using a watchdog timer. This is usually a timer that the MCU is supposed to reset at regular intervals, but the timer overflows when the routine does not return normally. However, if the main MCU unit 20 does not respond through the Watchdog pin during the watchdog time, the sub MCU unit 30 receives information on the status of the main MCU unit 20 through SPI (Serial Peripheral Interface Bus) communication have.

The sub MCU unit 30 monitors the state of the main MCU unit 20 to determine whether the main MCU unit 20 is faulty.

The sub MCU unit 30 shown in FIG. 1 outputs a High signal (EN_SUB line) to the sub activation line (EN_SUB line) of the EPB driving unit 10 when the main MCU unit 20 has a hardware failure as a result of the determination by the sub MCU unit 30 . In this case, the sub MCU unit 30 turns off the transistor 15 shown in FIG. 1 and blocks the main MCU unit 20 from applying the PWM signal to the EPB driver 10. 1 by applying a high signal to the sub activation line (EN_SUB line) of the EPB driving unit 10 shown in FIG. 1, regardless of the signal of the main activation line (EN_MAIN line) of the EPB driving unit 10 shown in FIG. (30) activates the motor drive (11) of the EPB driver (10). Subsequently, the sub MCU unit 30 directly applies the PWM signal to the PWM_SUB line of the EPB driving unit 10 shown in FIG. 1 to control the EPB driving unit 10.

The sub MCU unit 30 branches the main MCU unit 20 to an emergency interruption in software and outputs the emergency interruption to the main MCU unit 20 when the main MCU unit 20 is determined to be a software failure, Thereby controlling the EPB driver 10.

When the main MCU unit 20 is in operation and the EPB driving unit 10 is in operation and the main MCU unit 20 is in hardware failure, the sub MCU unit 30 determines whether the main MCU unit 20 is operating. The sub MCU unit 30 can control the EPB driving unit 10 in place of the sub-MCU unit 20. Thus, the sub MCU unit 30 can release the EPB driving unit 10 from being locked (Release operation).

When the main MCU unit 20 is in operation and the EPB driving unit 10 is operating and the main MCU unit 20 is in software failure, the sub MCU unit 30 determines whether the main MCU unit 20 is operating. The main MCU unit 20 branches the main MCU unit 20 to the emergency interrupt so that the main MCU unit 20 can control the EPB driving unit 10. [ Thus, the main MCU unit 20 can release the EPB driving unit 10 from being in the locked state (Release operation).

During the releasing operation, a High signal is input to the main fail safe line (Fail / Safe_MAIN), and a Low signal is inputted to the sub fail safe line (Fail / Safe_SUB). At this time, the EPB driving unit 10 is controlled by the sub MCU unit 30. After the release operation, a High signal is input to the sub-fail safe line (Fail / Safe_SUB). At this time, the EPB driving unit 10 does not operate.

In addition, the sub MCU unit 30 may further include a warning unit 40 for notifying the driver of the main MCU unit 20 of the failure when the main MCU unit 20 is faulty.

Hereinafter, an EPB control method according to an embodiment of the present invention will be described with reference to FIG.

2 is a flowchart sequentially illustrating a process of controlling an EPB of an EPB control apparatus according to an embodiment of the present invention.

First, the main MCU unit 20 and the sub MCU unit 30 wait for an operation request of the EPB driving unit 10 (S101).

When an operation request of the EPB driving unit 10 is received, the sub MCU unit 30 determines whether the main MCU unit 20 is operating normally (S103).

The process of determining whether the sub MCU unit 30 normally operates the main MCU unit 20 determines whether or not the sub MCU unit 30 monitors the state of the main MCU unit 20.

The sub-MCU unit 30 monitors the state of the main MCU unit 20 basically by using a watchdog timer. This is usually a timer that the MCU is supposed to reset at regular intervals, but the timer overflows when the routine does not return normally. However, if the main MCU unit 20 does not respond through the Watchdog pin during the watchdog time, the sub MCU unit 30 receives information on the status of the main MCU unit 20 through SPI (Serial Peripheral Interface Bus) communication have.

When the main MCU unit 20 normally operates in step S103, the main MCU unit 20 controls the EPB driving unit 10 (S105).

The main MCU unit 20 controls the EPB driving unit 10 by applying a high signal to the main EPB activation line (EN_MAIN line) of the EPB driving unit 10 shown in FIG. 1 to operate the EPB driving unit 10 . Thereafter, a PWM (Pulse Width Modulation) signal is applied to the main PWM signal input line (PWM_MAIN line) of the EPB driving unit 10 to control the EPB driving unit 10. In this case, a Low signal is applied to the sub EPB activation line (EN_SUB line), a High signal is applied to the main fail safe line (Fail / Safe_MAIN), and a Low signal is inputted to the sub fail safe line (Fail / Safe_SUB). At this time, the EPB driving unit 10 is controlled by the main MCU unit 20.

Thereafter, the EPB driving unit 10 operates under the control of the main MCU unit 20 (S107).

If the main MCU unit 20 does not operate normally in step S103, the sub MCU unit 30 receives error information through the main MCU unit 20 (S109).

If the sub MCU unit 30 receives the error information through the main MCU unit 20 in step S109, the sub MCU unit 30 determines whether the EPB driving unit 10 is in an operating state (S111).

If it is determined in operation S111 that the EPB driving unit 10 is in the operating state, the sub MCU unit 30 determines whether the main MCU unit 20 is a hardware malfunction (S113).

If it is determined in step S113 that the MCU unit 20 has a hardware failure, the sub MCU unit 30 controls the EPB driver 10 (S115).

Controlling the EPB driving unit 10 by the sub MCU unit 30 first applies a high signal to the sub activation line (EN_SUB line) of the EPB driving unit 10 shown in FIG. In this case, the sub MCU unit 30 turns off the transistor 15 shown in FIG. 1 and blocks the main MCU unit 20 from applying the PWM signal to the EPB driver 10. 1 by applying a high signal to the sub activation line (EN_SUB line) of the EPB driving unit 10 shown in FIG. 1, regardless of the signal of the main activation line (EN_MAIN line) of the EPB driving unit 10 shown in FIG. (30) activates the motor driver (11) of the EPB driver (10). Then, the sub MCU unit 30 directly applies the PWM signal to the sub PWM signal input line (PWN_SUB line) of the EPB driving unit 10 shown in FIG. 1 to control the EPB driving unit 10.

If it is determined in step S113 that the MCU unit 20 is a software malfunction, the sub MCU unit 30 branches the main MCU unit 20 to the emergency interruption in software, and the main MCU unit 20 controls the EPB driver 10 (S117).

If the sub MCU unit 30 controls the EPB driving unit 10 in step S115, the sub MCU unit 30 can cancel the locked state of the EPB driving unit 10, or in step S117, When the control unit 20 controls the EPB driving unit 10, the main MCU unit 20 can release the locked state of the EPB driving unit 10 (S119).

A high signal is input to the main fail safe line (Fail / Safe_MAIN) while a low signal is inputted to the sub fail safe line (Fail / Safe_SUB) while the EPB driving unit 10 is released from the locked state. At this time, the EPB driving unit 10 is controlled by the sub MCU unit 30. Also, after the EPB driving unit 10 is released from the locked state, a High signal is inputted to the sub fail safe line (Fail / Safe_SUB). At this time, the EPB driving unit 10 does not operate.

If it is determined in step S111 that the EPB driving unit 10 is not in operation, or after the EPB driving unit 10 is released from the locked state in step S119, the driver of the vehicle is notified of the failure of the main MCU unit 20 ).

It will be understood by those skilled in the art that the present specification may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. The scope of the present specification is defined by the appended claims rather than the foregoing detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents are included in the scope of the present specification Should be interpreted.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is not intended to limit the scope of the specification. It will be apparent to those skilled in the art that other modifications based on the technical idea of the present invention are possible in addition to the embodiments disclosed herein.

100: EPB control device
10: EPB driver
11: EPB motor
13: Motor driver
15: transistor
20: Main MCU part
30: Sub MCU unit
40: Warning section

Claims (11)

An EPB driver for driving an EPB (Electronic Parking Brake);
A main MCU unit for controlling the EPB driving unit; And
Wherein the control unit monitors the state of the main MCU unit and determines whether the main MCU unit is faulty as a result of the monitoring and controls the EPB driving unit to act as the main MCU unit when the main MCU unit has a hardware failure, The sub MCU unit branches the main MCU unit to an emergency interrupt so that the main MCU unit controls the EPB driving unit.
The method according to claim 1,
The sub MCU unit determines whether the EPB driving unit is in operation when the main MCU unit is in failure and controls the sub MCU unit to control the EPB driving unit when the EPB driving unit is in operation and the main MCU unit is in hardware failure, Vehicle EPB control device.
3. The method of claim 2,
Wherein the sub MCU unit branches the main MCU unit to an emergency interruption so that the main MCU unit controls the EPB driving unit when the EPB driving unit is in operation and the main MCU unit is in software failure.
The method according to claim 1,
Wherein the main MCU unit applies a high signal to the EPB driving unit to operate the EPB driving unit and applies a pulse width modulation (PWM) signal to the EPB driving unit to control the EPB driving unit.
The method according to claim 1,
When the main MCU unit has a hardware failure, the sub MCU unit applies a high signal to the EPB driving unit to block the PWM signal from being applied to the EPB driving unit by the main MCU unit, and applies the PWM signal directly to the EPB driving unit And controls the EPB driving unit.
The method according to claim 1,
And a warning unit for informing a vehicle driver of a failure of the main MCU unit when the main MCU unit fails as a result of the determination in the sub MCU unit.
A monitoring step of monitoring a state of the main MCU part;
A failure determination step of determining whether the main MCU is faulty through the monitoring result;
A first control step of causing the sub MCU unit to control the EPB driving unit in place of the main MCU unit when the main MCU unit has a hardware failure;
And a second control step of causing the sub MCU to branch the main MCU part to an emergency interruption when the main MCU part is a software malfunction so that the main MCU part controls the EPB driving part.
8. The method of claim 7,
Further comprising an operation judging step of judging whether the EPB driving unit is in operation when the main MCU unit is faulty,
Wherein the first control step causes the sub MCU to control the EPB driver when the EPB driver is in operation and the main MCU is in hardware failure.
9. The method of claim 8,
Wherein the second control step causes the main MCU unit to branch to the emergency interruption so that the main MCU unit controls the EPB driving unit when the EPB driving unit is in operation and the main MCU unit is in software failure.
8. The method of claim 7,
In the first control step, the sub MCU unit applies a high signal to the EPB driving unit to block the main MCU from applying the PWM signal to the EPB driving unit, and then the sub MCU unit supplies the PWM signal To control the EPB driving unit.
8. The method of claim 7,
Further comprising a warning step of informing a vehicle driver of a failure of the main MCU unit when the main MCU unit fails as a result of the determination in the sub MCU unit.

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